2020
DOI: 10.1038/s41586-020-2593-1
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Liquid–liquid transition and critical point in sulfur

Abstract: A liquid-liquid transition (LLT) is a peculiar phenomenon in which a singlecomponent liquid transforms into another one via a first-order phase transition. Due to their counterintuitive nature, LLTs have intrigued scientists for several years and changed our perception of the liquid state. Such LLTs have been predicted from computer simulations of water 1,2 , silicon 3 , carbon dioxide 4 , carbon 5 , hydrogen 6 and nitrogen 7. Experimental evidence has been mostly found in supercooled, i.e. metastable, liquids… Show more

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Cited by 89 publications
(54 citation statements)
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“…Correspondingly, the structure factor shows a shift in the first peak to a larger wavenumber q, while the second peak changes due to polymerization. This change is similar to what was observed in a recent experiment on sulfur [6]. In addition, S(q) shows a dramatic increase as q → 0 for the points corresponding to the equilibrium between two liquid phases (see Fig.…”
Section: Results: Liquid-liquid Phase Transitionsupporting
confidence: 89%
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“…Correspondingly, the structure factor shows a shift in the first peak to a larger wavenumber q, while the second peak changes due to polymerization. This change is similar to what was observed in a recent experiment on sulfur [6]. In addition, S(q) shows a dramatic increase as q → 0 for the points corresponding to the equilibrium between two liquid phases (see Fig.…”
Section: Results: Liquid-liquid Phase Transitionsupporting
confidence: 89%
“…In (a), the sharp peak, around r = 1 (in units of σ), corresponds to the length of the covalent bond, which increases upon increasing density. Simultaneously, in (b), the maximum of the structure factor (the first peak) shifts to larger wavenumbers upon increasing density, while the second peak acquires a characteristic bump, similar to what was recently observed in sulfur [6]. The divergence of the structure factor at q = 0 indicates the divergence of the isothermal compressibility in the vicinity of the LLCP.…”
Section: Critical Points: Comparison With Sulfursupporting
confidence: 80%
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“…In spite of these structural regularities and the miscibility for all concentrations of S-Se, S-Te (with a gap [12,13]), and Se-Te [14,15], the disordered phases of S, Se, and Te differ greatly, as emphasized in a recent review [16]. It has been known for over a century [17] that the viscosity of liquid S increases by several orders of magnitude near 160 • C. This is usually attributed to the ring-opening polymerization of S 8 units [18], and very recent combined density, x-ray diffraction, and Raman scattering measurements in sulfur indicate * r.jones@fz-juelich.de the presence of a liquid-liquid first-order phase transition and critical point at pressures up to 3 GPa [19]. Eisenberg and Tobolsky [20] proposed that a ring-chain transition also occurred in Se at 356 K, i.e., below the melting point (494 K).…”
Section: Introductionmentioning
confidence: 99%
“…Проблема полиморфизма веществ в жидком состоянии сохраняет актуальность, что нашло отражение, например, в новом обстоятельном обзоре на эту тему [44], где представлены итоги экспериментальных и теоретических исследований фазовых переходов в однокомпонентных жидких и аморфных средах, в основном на уровне 2019 г. В статье [44] проанализированы новые уникальные опытные данные по фазовой T −p-диаграмме серы [45]. Диаграмма включает линию ФП-2 и ее пересечение с линией равновесия жидкой и твердой фаз.…”
Section: заключениеunclassified